network_test.go - third_party/github.com/docker/docker - Git at Google

 package docker

 import (
 	"net"
 	"os"
 	"testing"
 )

 func TestIptables(t *testing.T) {
 	if err := iptables("-L"); err != nil {
 		t.Fatal(err)
 	}
 	path := os.Getenv("PATH")
 	os.Setenv("PATH", "")
 	defer os.Setenv("PATH", path)
 	if err := iptables("-L"); err == nil {
 		t.Fatal("Not finding iptables in the PATH should cause an error")
 	}
 }

 func TestNetworkRange(t *testing.T) {
 	// Simple class C test
 	_, network, _ := net.ParseCIDR("192.168.0.1/24")
 	first, last := networkRange(network)
 	if !first.Equal(net.ParseIP("192.168.0.0")) {
 		t.Error(first.String())
 	}
 	if !last.Equal(net.ParseIP("192.168.0.255")) {
 		t.Error(last.String())
 	}
 	if size := networkSize(network.Mask); size != 256 {
 		t.Error(size)
 	}

 	// Class A test
 	_, network, _ = net.ParseCIDR("10.0.0.1/8")
 	first, last = networkRange(network)
 	if !first.Equal(net.ParseIP("10.0.0.0")) {
 		t.Error(first.String())
 	}
 	if !last.Equal(net.ParseIP("10.255.255.255")) {
 		t.Error(last.String())
 	}
 	if size := networkSize(network.Mask); size != 16777216 {
 		t.Error(size)
 	}

 	// Class A, random IP address
 	_, network, _ = net.ParseCIDR("10.1.2.3/8")
 	first, last = networkRange(network)
 	if !first.Equal(net.ParseIP("10.0.0.0")) {
 		t.Error(first.String())
 	}
 	if !last.Equal(net.ParseIP("10.255.255.255")) {
 		t.Error(last.String())
 	}

 	// 32bit mask
 	_, network, _ = net.ParseCIDR("10.1.2.3/32")
 	first, last = networkRange(network)
 	if !first.Equal(net.ParseIP("10.1.2.3")) {
 		t.Error(first.String())
 	}
 	if !last.Equal(net.ParseIP("10.1.2.3")) {
 		t.Error(last.String())
 	}
 	if size := networkSize(network.Mask); size != 1 {
 		t.Error(size)
 	}

 	// 31bit mask
 	_, network, _ = net.ParseCIDR("10.1.2.3/31")
 	first, last = networkRange(network)
 	if !first.Equal(net.ParseIP("10.1.2.2")) {
 		t.Error(first.String())
 	}
 	if !last.Equal(net.ParseIP("10.1.2.3")) {
 		t.Error(last.String())
 	}
 	if size := networkSize(network.Mask); size != 2 {
 		t.Error(size)
 	}

 	// 26bit mask
 	_, network, _ = net.ParseCIDR("10.1.2.3/26")
 	first, last = networkRange(network)
 	if !first.Equal(net.ParseIP("10.1.2.0")) {
 		t.Error(first.String())
 	}
 	if !last.Equal(net.ParseIP("10.1.2.63")) {
 		t.Error(last.String())
 	}
 	if size := networkSize(network.Mask); size != 64 {
 		t.Error(size)
 	}
 }

 func TestConversion(t *testing.T) {
 	ip := net.ParseIP("127.0.0.1")
 	i := ipToInt(ip)
 	if i == 0 {
 		t.Fatal("converted to zero")
 	}
 	conv := intToIp(i)
 	if !ip.Equal(conv) {
 		t.Error(conv.String())
 	}
 }

 func TestIPAllocator(t *testing.T) {
 	expectedIPs := []net.IP{
 		0: net.IPv4(127, 0, 0, 2),
 		1: net.IPv4(127, 0, 0, 3),
 		2: net.IPv4(127, 0, 0, 4),
 		3: net.IPv4(127, 0, 0, 5),
 		4: net.IPv4(127, 0, 0, 6),
 	}

 	gwIP, n, _ := net.ParseCIDR("127.0.0.1/29")
 	alloc := newIPAllocator(&net.IPNet{IP: gwIP, Mask: n.Mask})
 	// Pool after initialisation (f = free, u = used)
 	// 2(f) - 3(f) - 4(f) - 5(f) - 6(f)
 	//  ↑

 	// Check that we get 5 IPs, from 127.0.0.2–127.0.0.6, in that
 	// order.
 	for i := 0; i < 5; i++ {
 		ip, err := alloc.Acquire()
 		if err != nil {
 			t.Fatal(err)
 		}

 		assertIPEquals(t, expectedIPs[i], ip)
 	}
 	// Before loop begin
 	// 2(f) - 3(f) - 4(f) - 5(f) - 6(f)
 	//  ↑

 	// After i = 0
 	// 2(u) - 3(f) - 4(f) - 5(f) - 6(f)
 	//         ↑

 	// After i = 1
 	// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
 	//                ↑

 	// After i = 2
 	// 2(u) - 3(u) - 4(u) - 5(f) - 6(f)
 	//                       ↑

 	// After i = 3
 	// 2(u) - 3(u) - 4(u) - 5(u) - 6(f)
 	//                              ↑

 	// After i = 4
 	// 2(u) - 3(u) - 4(u) - 5(u) - 6(u)
 	//  ↑

 	// Check that there are no more IPs
 	_, err := alloc.Acquire()
 	if err == nil {
 		t.Fatal("There shouldn't be any IP addresses at this point")
 	}

 	// Release some IPs in non-sequential order
 	alloc.Release(expectedIPs[3])
 	// 2(u) - 3(u) - 4(u) - 5(f) - 6(u)
 	//                       ↑

 	alloc.Release(expectedIPs[2])
 	// 2(u) - 3(u) - 4(f) - 5(f) - 6(u)
 	//                       ↑

 	alloc.Release(expectedIPs[4])
 	// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
 	//                       ↑

 	// Make sure that IPs are reused in sequential order, starting
 	// with the first released IP
 	newIPs := make([]net.IP, 3)
 	for i := 0; i < 3; i++ {
 		ip, err := alloc.Acquire()
 		if err != nil {
 			t.Fatal(err)
 		}

 		newIPs[i] = ip
 	}
 	// Before loop begin
 	// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
 	//                       ↑

 	// After i = 0
 	// 2(u) - 3(u) - 4(f) - 5(u) - 6(f)
 	//                              ↑

 	// After i = 1
 	// 2(u) - 3(u) - 4(f) - 5(u) - 6(u)
 	//                ↑

 	// After i = 2
 	// 2(u) - 3(u) - 4(u) - 5(u) - 6(u)
 	//                       ↑

 	assertIPEquals(t, expectedIPs[3], newIPs[0])
 	assertIPEquals(t, expectedIPs[4], newIPs[1])
 	assertIPEquals(t, expectedIPs[2], newIPs[2])

 	_, err = alloc.Acquire()
 	if err == nil {
 		t.Fatal("There shouldn't be any IP addresses at this point")
 	}
 }

 func assertIPEquals(t *testing.T, ip1, ip2 net.IP) {
 	if !ip1.Equal(ip2) {
 		t.Fatalf("Expected IP %s, got %s", ip1, ip2)
 	}
 }
	package docker

	import (
	"net"
	"os"
	"testing"
	)

	func TestIptables(t *testing.T) {
	if err := iptables("-L"); err != nil {
	t.Fatal(err)
	}
	path := os.Getenv("PATH")
	os.Setenv("PATH", "")
	defer os.Setenv("PATH", path)
	if err := iptables("-L"); err == nil {
	t.Fatal("Not finding iptables in the PATH should cause an error")
	}
	}

	func TestNetworkRange(t *testing.T) {
	// Simple class C test
	_, network, _ := net.ParseCIDR("192.168.0.1/24")
	first, last := networkRange(network)
	if !first.Equal(net.ParseIP("192.168.0.0")) {
	t.Error(first.String())
	}
	if !last.Equal(net.ParseIP("192.168.0.255")) {
	t.Error(last.String())
	}
	if size := networkSize(network.Mask); size != 256 {
	t.Error(size)
	}

	// Class A test
	_, network, _ = net.ParseCIDR("10.0.0.1/8")
	first, last = networkRange(network)
	if !first.Equal(net.ParseIP("10.0.0.0")) {
	t.Error(first.String())
	}
	if !last.Equal(net.ParseIP("10.255.255.255")) {
	t.Error(last.String())
	}
	if size := networkSize(network.Mask); size != 16777216 {
	t.Error(size)
	}

	// Class A, random IP address
	_, network, _ = net.ParseCIDR("10.1.2.3/8")
	first, last = networkRange(network)
	if !first.Equal(net.ParseIP("10.0.0.0")) {
	t.Error(first.String())
	}
	if !last.Equal(net.ParseIP("10.255.255.255")) {
	t.Error(last.String())
	}

	// 32bit mask
	_, network, _ = net.ParseCIDR("10.1.2.3/32")
	first, last = networkRange(network)
	if !first.Equal(net.ParseIP("10.1.2.3")) {
	t.Error(first.String())
	}
	if !last.Equal(net.ParseIP("10.1.2.3")) {
	t.Error(last.String())
	}
	if size := networkSize(network.Mask); size != 1 {
	t.Error(size)
	}

	// 31bit mask
	_, network, _ = net.ParseCIDR("10.1.2.3/31")
	first, last = networkRange(network)
	if !first.Equal(net.ParseIP("10.1.2.2")) {
	t.Error(first.String())
	}
	if !last.Equal(net.ParseIP("10.1.2.3")) {
	t.Error(last.String())
	}
	if size := networkSize(network.Mask); size != 2 {
	t.Error(size)
	}

	// 26bit mask
	_, network, _ = net.ParseCIDR("10.1.2.3/26")
	first, last = networkRange(network)
	if !first.Equal(net.ParseIP("10.1.2.0")) {
	t.Error(first.String())
	}
	if !last.Equal(net.ParseIP("10.1.2.63")) {
	t.Error(last.String())
	}
	if size := networkSize(network.Mask); size != 64 {
	t.Error(size)
	}
	}

	func TestConversion(t *testing.T) {
	ip := net.ParseIP("127.0.0.1")
	i := ipToInt(ip)
	if i == 0 {
	t.Fatal("converted to zero")
	}
	conv := intToIp(i)
	if !ip.Equal(conv) {
	t.Error(conv.String())
	}
	}

	func TestIPAllocator(t *testing.T) {
	expectedIPs := []net.IP{
	0: net.IPv4(127, 0, 0, 2),
	1: net.IPv4(127, 0, 0, 3),
	2: net.IPv4(127, 0, 0, 4),
	3: net.IPv4(127, 0, 0, 5),
	4: net.IPv4(127, 0, 0, 6),
	}

	gwIP, n, _ := net.ParseCIDR("127.0.0.1/29")
	alloc := newIPAllocator(&net.IPNet{IP: gwIP, Mask: n.Mask})
	// Pool after initialisation (f = free, u = used)
	// 2(f) - 3(f) - 4(f) - 5(f) - 6(f)
	// ↑

	// Check that we get 5 IPs, from 127.0.0.2–127.0.0.6, in that
	// order.
	for i := 0; i < 5; i++ {
	ip, err := alloc.Acquire()
	if err != nil {
	t.Fatal(err)
	}

	assertIPEquals(t, expectedIPs[i], ip)
	}
	// Before loop begin
	// 2(f) - 3(f) - 4(f) - 5(f) - 6(f)
	// ↑

	// After i = 0
	// 2(u) - 3(f) - 4(f) - 5(f) - 6(f)
	// ↑

	// After i = 1
	// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
	// ↑

	// After i = 2
	// 2(u) - 3(u) - 4(u) - 5(f) - 6(f)
	// ↑

	// After i = 3
	// 2(u) - 3(u) - 4(u) - 5(u) - 6(f)
	// ↑

	// After i = 4
	// 2(u) - 3(u) - 4(u) - 5(u) - 6(u)
	// ↑

	// Check that there are no more IPs
	_, err := alloc.Acquire()
	if err == nil {
	t.Fatal("There shouldn't be any IP addresses at this point")
	}

	// Release some IPs in non-sequential order
	alloc.Release(expectedIPs[3])
	// 2(u) - 3(u) - 4(u) - 5(f) - 6(u)
	// ↑

	alloc.Release(expectedIPs[2])
	// 2(u) - 3(u) - 4(f) - 5(f) - 6(u)
	// ↑

	alloc.Release(expectedIPs[4])
	// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
	// ↑

	// Make sure that IPs are reused in sequential order, starting
	// with the first released IP
	newIPs := make([]net.IP, 3)
	for i := 0; i < 3; i++ {
	ip, err := alloc.Acquire()
	if err != nil {
	t.Fatal(err)
	}

	newIPs[i] = ip
	}
	// Before loop begin
	// 2(u) - 3(u) - 4(f) - 5(f) - 6(f)
	// ↑

	// After i = 0
	// 2(u) - 3(u) - 4(f) - 5(u) - 6(f)
	// ↑

	// After i = 1
	// 2(u) - 3(u) - 4(f) - 5(u) - 6(u)
	// ↑

	// After i = 2
	// 2(u) - 3(u) - 4(u) - 5(u) - 6(u)
	// ↑

	assertIPEquals(t, expectedIPs[3], newIPs[0])
	assertIPEquals(t, expectedIPs[4], newIPs[1])
	assertIPEquals(t, expectedIPs[2], newIPs[2])

	_, err = alloc.Acquire()
	if err == nil {
	t.Fatal("There shouldn't be any IP addresses at this point")
	}
	}

	func assertIPEquals(t *testing.T, ip1, ip2 net.IP) {
	if !ip1.Equal(ip2) {
	t.Fatalf("Expected IP %s, got %s", ip1, ip2)
	}
	}